13.7
During DNA replication, free nucleotides in the cell are added to the new strand in a sequence complementary to the template. Adenine pairs with thymine, and cytosine pairs with guanine.
Sometimes, nucleotides pair incorrectly, such as when adenine pairs with cytosine. DNA polymerase proofreading helps fix these errors and reduces the chance of mutations. If they are not corrected, these errors can cause disease.
First, DNA polymerase binds more strongly to correctly paired nucleotides. This reduces the chance of incorrect pairings.
Second, as nucleotides begin pairing with the template, DNA polymerase undergoes a conformational change. This change causes incorrectly paired nucleotides to detach, allowing the correct nucleotides to be added.
Third, if an incorrect nucleotide is added to the three-prime end of the growing DNA chain, the mismatch distorts the DNA structure and pauses DNA polymerase movement.
DNA polymerase has three-prime-to-five-prime exonuclease activity, which lets it remove an incorrectly added nucleotide. It then inserts the correct nucleotide. This process is called exonucleolytic proofreading.
These steps help keep DNA replication accurate by separating nucleotide selection from error correction.
Synthesis of new DNA molecules starts when DNA polymerase links nucleotides together in a sequence that is complementary to the template DNA strand. DNA polymerase has a higher affinity for the correct base to ensure fidelity in DNA replication. The DNA polymerase furthermore proofreads during replication, using an exonuclease domain that cuts off incorrect nucleotides from the nascent DNA strand.
Genomic DNA is synthesized in the 5’ to 3’ direction. Each cell contains a number of DNA polymerases that play different roles in synthesizing and correcting mistakes in DNA; DNA polymerase delta and epsilon possess proofreading ability when replicating nuclear DNA. These polymerases “read” each base after it is added to the new strand. If the newly-added base is incorrect, the polymerase reverses direction (moving from 3’ to 5’) and uses an exonucleolytic domain to cut off the incorrect base. Subsequently, it is replaced with the correct base.
Proofreading is important for preventing mutations from occurring in newly-synthesized DNA, but what happens when the proofreading mechanism fails? When a mutation alters the exonuclease domain of DNA polymerase, it loses the ability to remove incorrect nucleotides. In consequence, mutations can accumulate rapidly throughout the genome. This type of mutation has been linked to various types of cancer.
Modified DNA polymerases are used in laboratory science for polymerase chain reaction (PCR), an in vitro technique for making many copies of specific fragments of DNA. While high-fidelity polymerases are used when it is important that the end product is perfect, some techniques, such as error-prone PCR, seek to generate mutations in a stretch of DNA on purpose. These techniques use polymerases that have compromised proofreading ability.
During DNA replication, free nucleotides in the cell are added to the new strand in a sequence complementary to the template. Adenine pairs with thymine, and cytosine pairs with guanine.
Sometimes, nucleotides pair incorrectly, such as when adenine pairs with cytosine. DNA polymerase proofreading helps fix these errors and reduces the chance of mutations. If they are not corrected, these errors can cause disease.
First, DNA polymerase binds more strongly to correctly paired nucleotides. This reduces the chance of incorrect pairings.
Second, as nucleotides begin pairing with the template, DNA polymerase undergoes a conformational change. This change causes incorrectly paired nucleotides to detach, allowing the correct nucleotides to be added.
Third, if an incorrect nucleotide is added to the three-prime end of the growing DNA chain, the mismatch distorts the DNA structure and pauses DNA polymerase movement.
DNA polymerase has three-prime-to-five-prime exonuclease activity, which lets it remove an incorrectly added nucleotide. It then inserts the correct nucleotide. This process is called exonucleolytic proofreading.
These steps help keep DNA replication accurate by separating nucleotide selection from error correction.
From Chapter 13:
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